Adaptive heating control system for a water heater

ABSTRACT

A water heating control system for automatically reducing delay in delivering a volume of water at a flowrate, the volume of water is heated from a first temperature to a target temperature during a time interval of a day, the water heating system includes a device for aiding in heating the volume of water from the first temperature to the target temperature, a historical flow demand corresponding to the time interval of a day, a current flow demand corresponding to the time interval of a day and a controller configured for calculating a new flow demand from the historical flow demand and the current flow demand. The new flow demand is set as the historical flow demand for the time interval of a day and if the new flow demand exceeds a threshold, the device is configured to be activated during the time interval of a day.

FIELD OF INVENTION

This invention relates to a control system for water heaters, and more specifically, to an adaptive control system for water heaters based on the present and historical usage of hot water.

BACKGROUND ART

Most water heaters are capable of delivering water at a desired temperature in steady state conditions where the water demand or flow rate is substantially constant. However, water heating systems presently available or prior art water heating systems fall short when attempting to maintain a water output at a constant predetermined temperature level during rapid shifts or fluctuations in water demand. It is understood that the demand for water is directly related to the output flow rate requested from the water heating system. Prior art water heating systems will provide the water output flow rate corresponding to the water demand placing the predetermined temperature setting as a secondary consideration. Placing predetermined water output temperature as a secondary consideration creates two major thermal related problems. The first issue is encountered during a rapid increase in water demand, wherein the user or device experiences a sudden drop in water temperature or a cold water splash. The remaining issue occurs during a rapid decrease in water demand, wherein the user or device experiences a sudden spike in water temperature, thereby creating a possible burn or scald type hazard. Furthermore, none of the prior art water heaters are capable of delivering water at the predetermined or desired temperature range without substantial delays. The rapid shifts in water demand creates a transient condition within the water heating system wherein such existing systems are ill equipped to handle.

On-demand water heaters are gaining popularity because of their reduced space requirement in addition to improved energy advantages. The current on-demand water heaters have well known drawbacks, most notably, the uncontrollable and undesirable fluctuation of temperature of the output water during water usage. When output water flow increases, the temperature of the output water decreases. Conversely, when output water flow decreases, the temperature of the output water increases. This creates undesirable temperature fluctuations for users, appliances, and the like. Disadvantages of these tankless water heaters are well known in the art and general population, such a discussion is described in Wikipedia, and reads as follows:

-   -   Installing a tankless system comes at an increased cost,         particularly in retro-fit applications. They tend to be         particularly expensive in areas such as the US where they are         not dominant, compared to the established tank design. If a         storage water heater is being replaced with a tankless one, the         size of the electrical wiring or gas pipeline may have to be         increased to handle the load and the existing vent pipe may have         to be replaced, possibly adding expense to the retrofit         installation. Many tankless units have fully modulating gas         valves that can range from as low as 10,000 to over 1,000,000         BTUs. For electrical installations (non-gas), AWG 10 or 8 wire,         corresponding to 10 or 6 mm², is required for most POU (point of         use) heaters at North American voltages. Larger whole house         electric units may require up to AWG 2 wire. In gas appliances,         both pressure and volume requirements must be met for optimum         operation.     -   There is a longer wait to obtain hot water. A tankless water         heater only heats water upon demand, so all idle water in the         piping starts at room temperature. Thus there is a more apparent         “flow delay” for hot water to reach a distant faucet.     -   There is a short delay between the time when the water begins         flowing and when the heater's flow detector activates the         heating elements or gas burner. In the case of continuous use         applications (showers, baths, washing machine) this is not an         issue. However, for intermittent use applications (for example         when a hot water faucet is turned on and off repeatedly) this         can result in periods of hot water, then some small amount of         cold water as the heater activates, followed quickly by hot         water again. The period between hot/cold/hot is the amount of         water which has flowed though the heater before becoming active.         This cold section of water takes some amount of time to reach         the faucet and is dependent on the length of piping.     -   Since a tankless water heater is inactive when hot water is not         being used, they are incompatible with passive         (convection-based) hot water recirculation systems. They may be         incompatible with active hot water recirculation systems and         will certainly use more energy to constantly heat water within         the piping, defeating one of a tankless water heater's primary         advantages.     -   Tankless water heaters often have minimum flow requirements         before the heater is activated, and this can result in a gap         between the cold water temperature, and the coolest warm water         temperature that can be achieved with a hot and cold water mix.     -   Similarly, unlike with a tank heater, the hot water temperature         from a tankless heater is inversely proportional to the rate of         the water flow—the faster the flow, the less time the water         spends in the heating element being heated. Mixing hot and cold         water to the “right” temperature from a single-lever faucet         (say, when taking a shower) takes some practice. Also, when         adjusting the mixture in mid-shower, the change in temperature         will initially react as a tanked heater does, but this also will         change the flow rate of hot water. Therefore some finite time         later the temperature will change again very slightly and         require readjustment. This is typically not noticeable in         non-shower applications. A temperature compensating valve tends         to eliminate this issue. Tankless systems are reliant on the         water pressure that is delivered to the property. In other         words, if a tankless system is used to deliver water to a shower         or water faucet, the pressure is the same as the pressure         delivered to the property and cannot be increased, whereas in         tanked systems the tanks can be positioned above the water         outlets (in the loft/attic space for example) so the force of         gravity can assist in delivering the water, and pumps can be         added into the system to increase pressure. Power showers, for         example, cannot be used with tankless systems because it cannot         deliver the hot water at a fast enough flow-rate required by the         pump.

A typical water demand scenario is provided in the following example. A first user draws water at a desired temperature at a bathroom faucet while simultaneously a second user opens a kitchen faucet. The output water temperature experienced by both users dramatically decreases since the total flow rate through the water heater increases, and thus, the volume of water to be heated per unit of time has increased while the burner output remains constant (or the system is not capable of keeping pace with the increased water demand). At the other end of the spectrum, in a situation where two users are using water at desired temperature at two separate faucets, where one user closes a faucet, the remaining open faucet will experience a spike (dramatic increase) in temperature. This is due to a decrease in the volume of water to be heated per unit time resulting in a reduction of water flow through the water heater resulting in an increase in output water temperature.

Other well known drawbacks associated current on demand water heaters include the cold sandwich effect, freeze hazards, and dead zones. Controls for water heaters are plagued with limitations and lack the sophistication to maximize system efficiency.

The purpose of the present invention is to overcome several shortcomings in the aforementioned prior art as well as the introduction of additional novel features.

SUMMARY OF THE INVENTION

A water heating control system for automatically reducing delay in delivering a volume of water at a flowrate, the volume of water is heated from a first temperature to a target temperature during a time interval of a day, the water heating control system comprising:

-   -   (a) a device for aiding in heating the volume of water at the         flowrate from the first temperature to the target temperature;     -   (b) a historical flow demand corresponding to the time interval         of a day;     -   (c) a current flow demand corresponding to the time interval of         a day; and     -   (d) a controller configured for calculating a new flow demand         from the historical flow demand and the current flow demand,         wherein if the new flow demand exceeds a threshold, the device         is configured to be activated during the time interval of a day         and the new flow demand is configured to be set as the         historical flow demand for the time interval of a day.

The historical flow demand can be historical average flowrate, historical average flow volume, historical average frequency of flow request, historical frequency of user presence detection or any combinations thereof.

The current flow demand is sustained water flowrate of at or above about 0.5 Gallons Per Minute (GPM) for at least about 5 minutes.

In one embodiment, the current flow demand is the current flowrate.

The device can be an internal recirculating flow circuit, an external recirculating flow circuit, a burner, a burner and blower combination, a valve, a pump or any combinations thereof.

In one embodiment, the new flow demand is configured to be calculated by applying a first weighting factor to the historical flow demand to result in a first intermediate result and a second weighting factor to the current flow demand to result in a second intermediate result, wherein the second weighting factor is a complementary percentage of the first weighting factor.

In one embodiment, the time interval of a day covers a span of about 15 minutes.

In one embodiment, the device is an external recirculating flow circuit adapted to recirculate the volume of water in a variable volume holding tank.

It is an object of the present invention to minimize delay in the delivery of hot water by automatically preparing hot water based on the present and historical usage of hot water.

It is another object of the present invention to reduce wastes and wear and tear of devices due to pre-programmed activations of the devices relating to hot water heating.

It is another object of the present invention to prepare or heat only an amount of water considered sufficient to meet a demand during a time interval of a day such that the energy that would otherwise be used to heat unused hot water can be minimized.

Whereas there may be many embodiments of the present invention, each embodiment may meet one or more of the foregoing recited objects in any combination. It is not intended that each embodiment will necessarily meet each objective.

In this respect, before explaining at least one embodiment of the invention in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangements of the components set forth in the following description or illustrated in the drawings. The present invention is capable of other embodiments and of being practiced and carried out in various ways. Thus, having broadly outlined the more important features of the present invention in order that the detailed description thereof may be better understood, and that the present contribution to the art may be better appreciated, there are, of course, additional features of the present invention that will be described herein and will form a part of the subject matter of this specification.

PARTICULAR ADVANTAGES OF THE INVENTION

The present adaptive control system is provided to anticipate hot water demand during various time intervals of a day. In one embodiment, the current and historical flow demands are used to determine whether or not a heating aid such as a recirculation circuit, one or more valves, a burner, a burner and blower combination and any combinations thereof should be activated to reduce delay in preparing and delivering hot water to a user.

The present adaptive control system aids in reducing wastes and wear and tear due to pre-programmed activation of devices based on fixed schedule when there lacks a need for the activation of such devices. Over time, the present adaptive control system aids the devices it controls in adapting to perceived needs that are derived based on historical and present needs.

In one embodiment, the present adaptive control system is used in conjunction with a present variable volume holding tank to determine the volume of water to be heated in anticipating usage. An appropriate volume of water is made available in the holding tank based on perceived needs before it is heated to anticipate a usage. If a water volume deficit exists, more water will be added in the holding tank such that a sufficient amount of heated water may be provided. If a water volume surplus exists, less water will be taken in the holding tank during a time interval in anticipation of reduced perceived demand in the next time interval. In some cases where severely reduced perceived usage is anticipated, some water may even be drained from the holding tank such that a smaller amount of water is prepared to temperature, thereby requiring less heat to be put in the smaller volume of water. As the present adaptive control system “learns” the habits of hot water usage of an establishment, some amounts of water may need to be drained. However, over time and as the present adaptive control system learned the habits, less water will be wasted. This is in direct contrast to a pre-programmed system which requires human monitoring of water usage habits such that energy savings may be realized.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described by reference to the specification and the drawings, in which like numerals refer to like elements, and wherein:

FIG. 1 is one embodiment of a hot water heater system of the present invention;

FIG. 2 is a schematic block diagram of a preferred embodiment of a water heater controller of the water heater system of FIG. 1;

FIG. 3 is a schematic controls diagram of the water heater controller;

FIG. 4 depicts an alternate embodiment of a water heater;

FIG. 5 depicts an alternate embodiment of a water heater;

FIG. 6 is a table depicting an example of the flow data during several time intervals of a day.

FIG. 7 is a table depicting an example of the flow data during a time interval of a day for several days.

FIG. 8 is a sample water usage of a 300-room hotel on a weekday.

FIG. 9 is a sample water usage of the 300-room hotel of FIG. 8 on a weekend day.

FIG. 10 is a sample water usage of the 300-room hotel of FIG. 8 on another weekend day.

FIG. 11 is another embodiment of a hot water heating system of the present invention, depicting a variable volume holding tank used in conjunction with the present adaptive control system.

The drawings are not to scale, in fact, some aspects have been emphasized for a better illustration and understanding of the written description. For simplicity in representing the complex controls scheme, the diamonds in the block figures schematically represent input and/or output devices. Arrows pointing toward a diamond represent input devices, arrows pointing away from a diamond represent output devices and arrows both pointing toward and away from a diamond represent a dual input-output device.

PARTS LIST

-   2—hot water heater -   4—hot water heater enclosure -   6—flow path -   8—primary heating system (burner including heat exchanger) -   9—primary heating process -   10—inlet of water heater -   11—inlet flow -   12—outlet flow -   13—mixed flow for second point of demand -   14—thermal insulation for mixing buffer tank -   15—mixing buffer tank -   16—secondary heating element (electric heater) -   17—secondary heating process -   18—inlet temperature sensor -   19—external auxiliary device circuit -   21—mixed flow (for second point of demand) -   22—outlet temperature sensor -   23—outlet temperature sensor for auxiliary demand -   24—flow limiting valve -   25—internal recirculating flow circuit -   26—flow sensor -   27—external recirculating flow circuit -   28—recirculation pump -   29—blower speed feedback -   30—internal recirculation check valve -   31—portion of recirculation flow -   32—internal recirculating flow -   33—external recirculation check valve -   34—burner -   35—internal recirculation modulating valve -   36—blower -   36 a—blower fan speed control -   37—external recirculation modulating valve -   37 a—external recirculation flow -   38—controller -   39—temperature sensor (merged flow) -   40—flue gas exit -   41—merged flow temperature signal -   42—expansion tank -   43—user interface -   44—bypass flow (buffer tank) -   45—buffer tank bypass line -   46—moisture sensor -   47—external auxiliary device modulating valve -   48—differential pressure switch -   50—condensate level sensor -   52—flue gas temperature sensor -   53—external gas usage input signal -   54—buffer tank flow -   56—buffer tank bypass three way valve -   59—auxiliary three way valve -   60—capillary bypass line -   61—distal end of the heat exchanger -   64—auxiliary heat sink -   66—first demand point -   67—cold water point of demand -   68—second demand point -   70—outlet temperature (T_(outlet)) -   72—inlet temperature (T_(inlet)) -   74—desired temperature (T_(desired)) -   76—temperature difference (T_(desired)−T_(outlet)) -   78—temperature difference (T_(desired)−T_(inlet)) -   80—flow rate -   82—flue gas temperature -   84—flue gas temperature limit—flue gas temperature -   90—feedforward control -   92—feedback control -   94—main control -   96—safety control -   98—secondary heat control (electric heat) -   100—recirculation control -   102—flow limiting valve control -   104—differential pressure switch -   106—differential pressure signal -   108—flue temperature limit -   112—available power -   114—time interval -   116—current flowrate -   118—flow usage indicator -   120—average flow -   122—trigger for activating heating aid -   124—memory -   126—clock -   128—variable volume holding tank -   130—variable volume holding tank output flow sensor -   132—air valve -   134—air space -   136—liquid in tank -   138—input line to variable volume holding tank -   140—recirculation line -   142—drain valve -   144—recirculation direction for variable volume holding tank

Also it is to be understood that the phraseology and terminology employed herein are for the purpose of description and should not be regarded as limiting.

DEFINITIONS OF TERMS USED IN THIS SPECIFICATION

The term hybrid tankless water heating system shall have equivalent nomenclature including: the hybrid water heater, the heater, the device, the present invention, or the invention. As used in this specification, the following terms shall be defined as follows:

Hybrid water heater shall mean a water heater that combines two heating means, via a primary heating element and a secondary heating element, such as a gas burner and an electric immersion coil.

Usage is defined as units of “damage.”

“Damage” is a quantity of usage as seen in a water heater. “Damage” can include the effects of scaling, wear, burner cycles, amount of water delivered, etc. An increased usage of a water heater causes a corresponding increase in the amount of “damage.”

The efficiency of a water heating system is defined as the amount of converted thermal energy in the delivered water per unit of energy input. The efficiency of a water heater system is typically nonlinear with respect to flow rate.

The term “about” is used herein to mean approximately, roughly, around, or in the region of. When the term “about” is used in conjunction with a numerical range, it modifies that range by extending the boundaries above and below the numerical values set forth. In general, the term “about” is used herein to modify a numerical value above and below the stated value by a variance of 20 percent up or down (higher or lower).

Additionally, the term “exemplary” shall possess only one meaning in this disclosure; wherein the term “exemplary” shall mean: serving as an example, instance, or illustration.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

FIG. 1 illustrates one embodiment of a novel hybrid tankless water heater 2 (“water heater”) and the relative placement of various components of the system. Briefly described, the water heater 2 comprises an enclosure 4 having a thermally insulated mixing buffer tank 15 with baffles disposed downstream from a heat exchanger of a primary heating system 8. There is further provided a secondary heating element 16 to supply supplemental heat, preferably disposed in mixing buffer tank 15. The combination of two heating systems (such as gas and immersion electric) thus renders the present invention a “hybrid” water heater.

Optionally there is further provided a differential pressure switch 48 that functions to rapidly detect a need to turn on primary 8 or secondary 16 heating elements by detecting trickle or low flow. There is also provided an internal recirculating system 25 and an inverted burner system in primary heating system 8. The differential pressure switch is an important feature of the present invention in that it provides a means for fine controlling of output water temperature, a means for expedient temperature response to a demand, and a means for detecting leakage and activating associated alarms or alerts.

Other embodiments may include advantageous features described in greater detail below, including a moisture sensor in the enclosure, an integrated buffer and expansion tank or an independent expansion tank, a condensate level sensor, a capillary bypass line, a blower that operates independent of the burner and recirculation pump, and a feature that allows the user to set an automatic temperature rise rate and a high temperature limit. Yet other additional advantageous features are provided and described herein, including features to enhance user ability for self-maintenance of the water heater.

A demand at first demand point 66 causes a fluid flow to enter the water heater 2 at inlet 10 and exit water heater 2 at outlet 12. In the illustrative embodiment, water at first demand point 66 is not mixed with cold incoming water upon receiving heat from system heat sources (e.g., primary heating element 9 and secondary heating element 16), however, it is contemplated that water at first demand point 66 may be mixed with a cold water supply via a three way valve connection or other similar mechanism.

Continuing to refer to FIG. 1, water heater 2 includes a flow limiting valve 24 for restricting inlet flow 11. The flow limiting valve 24 controls the flow rate of water entering the water heater 2. Water heater 2 further includes an inlet water temperature sensor 18 to sense the inlet water temperature.

The internal recirculating flow circuit 25 facilitates an internal recirculating flow 32 that is merged with the inlet flow 11. This internal recirculating flow circuit 25 includes an internal recirculation modulating valve 35 and a check valve 30. Check valve 30 permits recirculation from outlet 12 end of water heater 2 to inlet 10 end and stops any flow from inlet 10 end to outlet 12 end of water heater 2 while the internal recirculation modulating valve 35 modulates the magnitude of internal recirculation flow 32 in a predetermined fashion.

The external recirculating flow circuit 27 comprises an external recirculation modulating valve 37 that modulates the magnitude of external recirculation flow 37 a. Flow circuit 27 includes an external recirculation check valve which permits only the flow of water from the heated outlet via the external cold water supply line back to the inlet of the heated, and a cold water point of demand 67 attached thereon.

Continuing to refer to FIG. 1, the inlet water temperature sensor 18 is placed upstream of the point where internal recirculating flow 32 and water flow from inlet 10 converge. The water heater 2 preferably includes a flow sensor 26 that is disposed upstream from the point where the internal recirculating flow 32 and water flow from inlet 10 converge. Temperature sensor 39 is placed at this point of convergence.

The water heater 2 has a primary heating element 9. In the embodiment depicted in FIG. 1, primary heating system 8 comprises a burner 34, a blower 36, a fuel supply valve, and a heat exchanger. The heat exchanger transfers heat from the burner 34 to the water flow. Preferably, the blower 36 is used in conjunction with the burner 34 to enhance mixing of the fuel with ambient air prior to combustion. The blower 36 can also enhance convectional heat transfer by forcing the hot flue gas to distal end of the heat exchanger 61 from burner 34.

Upon passing through the heat exchanger, the heated water enters a mixing buffer tank 15. The mixing buffer tank 15 serves as a reserve supply of warm water to ease excessively cold or warm water during transience. Preferably, mixing buffer tank 15 contains a secondary heating system. An immersion heating element is beneficial in this application. In the embodiment depicted, an electrical heating coil is used as a secondary heating element 16. When water flow at first demand point 66 exists, the flow from mixing buffer tank 15 can exit outlet 12 and/or it can recirculate. The water heater 2 can include outlet temperature sensor 22 at outlet 12 of the water heater 2. A decrease in temperature as indicated by outlet temperature sensor 22 over time can be used to detect a small flow.

A typical flow sensor requires a minimum flow in order to start registering a flow rate. However, a particular advantage is realized when a differential pressure switch 48 is utilized to detect a low flow condition such that it effectively covers the range of flow the flow sensor 26 is unable to detect. Specifically, flows greater than 0.005 Gallons Per Minute (GPM) can be detected with this arrangement. It is to be understood that differential pressure sensors that detect pressure and flows greater or lower than 0.005 GPM can be suitably used with the present invention. A detected flow causes primary heating element 9 and secondary heating element 16 to turn on and water to be recirculated in order to maintain the desired outlet temperature.

When a large amount of hot water is abruptly demanded, buffer tank 15 may not be capable of supplying the amount of hot water demanded. A buffer tank bypass three way valve 56 is provided to give water heater 2 the capability of supplying heated water directly to the point of use at the desired temperature. When the use of buffer tank 15 is desired, buffer tank bypass three way valve 56 is controlled such that bypass flow 44 is ceased. Conversely, if bypass is desired, the buffer tank flow 54 is ceased.

Continuing to refer to FIG. 1, water heater 2 further comprises an expansion tank 42. Fluid expands as it is heated, causing pressure in the water heater flow system to rise. Inclusion of expansion tank 42 provides a particular advantage in accommodating this fluid expansion and may be mounted any location in the fluid flow system which experiences fluid expansion. In another embodiment not shown, the function of an expansion tank is incorporated into the buffer tank 15, eliminating the need of an independent expansion tank. In the illustrative embodiment, expansion tank 42 is mounted at inlet 10 end of water heater 2.

FIG. 2 is a generalized block diagram of the water heater controller of the water heater 2 of FIG. 1 depicting the inputs and outputs to controller 38. At the heart of the water heater controller is general purpose controller 38, the comprehensive unit capable of receiving electrical signals, for example from sensors and switches, performing computations based on the signals and outputting electrical control signals as a result of the computations to actuate certain electrical or electro-mechanical components. In the present invention, controller 38 receives a plurality of sensor inputs and outputs a plurality of control signals to perform water heating control.

Referring to FIG. 2, user interface 43 is depicted as a bi-directional communication tool for a user to enter preferences manually or automatically provide control inputs from a second control device. User interface 43 also functions as a display for pertinent water heater 2 information or to provide control output to a second control device. Flow sensor 26 provides flow rate to controller 38 indicating user hot water demand from first demand point 66. In a system with multiple demand points, this flow rate could indicate the total flow rate of all of the demand points.

Outlet temperature sensor 22 provides a signal corresponding to the water temperature at outlet 12 of water heater 2 of a water pipeline leading to first demand point 66. In a system with multiple demand points, there is provided an outlet temperature sensor 22 for each outlet.

Inlet water temperature sensor 18 provides a signal corresponding to the water temperature at water heater inlet 10 of a water source. Preferably, moisture sensor 46 is mounted in the cavity of water heater enclosure 4, and provides a signal corresponding to the humidity in the cavity of water heater enclosure 4. This provides a significant advantage over the prior art in that a means for leak detection in the enclosure is provided. A differential pressure switch 48 provides a signal indicating the presence of a small demand from first demand point 66 in the water heater 2. A condensate level sensor 50 provides a signal indicating whether the condensate resulting from the condensing heat exchanger is draining properly. This provides a significant advantage over the prior art in that it provides a means for corrosion control and preventing overflow and the resulting mess. A flue gas temperature sensor 52 provides a signal corresponding to the flue gas temperature. An excessive flue gas temperature or temperature rise rate causes the controller to de-rate the burner to avoid potentially unsafe operation due to fire hazards and damage to the water heater 2. The means of detecting excessive heat is a significant advantage over the prior art by providing a manner to enhance safety and prevent equipment damage.

A control output is provided to control the water flow rate through the water heater 2 via a flow limiting valve 24. A control output is provided to control pump 28 speed. In one embodiment, the pump is a single speed pump. A control output is provided to control fuel flow rate of burner 34. A burner 34 is immediately lit when fuel is admitted at the burner 34. If the fuel valve is opened and a flame is not lit within a predetermined period of time (e.g., due to failed sparking or absence of fuel flow), the fuel valve will be shut off and retried after a predetermined period. A control output is provided to control a blower 36 fan speed. The blower 36 fan is used in conjunction with burner 34 in order to cause maximum heat transfer from burner 34 to the external surfaces of the heat exchanger. Blower 36 fan may also be turned on independent of burner 34 such as in the case where heat loss is desired of the heat exchanger tubes. Blower 36 speed control is further enhanced by the use of blower speed feedback 29.

A control output is provided to control the power output of a secondary heating element 16, in this case, an electric heating element. This electric heating element is used when the burner 34 is incapable of achieving the heating response desired independently or when burner 34 is incapable of providing a low heat rate. In one embodiment, the burner shutoff switch and the fuel shut off switch are a single integral switch unit. During low flow, the primary heating element (the burner) does not engage. When the flow is slightly above the level the secondary heating element (electric coil) can handle alone, pulse firing of the primary heating element will commence. Once the flow reaches a predetermined limit, the blower will be modulated to correspond to the flow demand. During periods of transience in flow, where the blower may be slow to respond, the secondary heating element will provide instantaneous, but limited, heat to the water.

A control output is provided to modulate the amount of fluid flowing through buffer tank 15. A buffer tank bypass three way valve 56 is used to divert flow from buffer tank 15 when the demand for hot water cannot be met by the water in buffer tank 15. The diverted water flows directly from the heat exchanger to the point of demand, avoiding cooling that occurs upon mixing with cooler water stored in buffer tank 15. A control output is provided to modulate the recirculation flow rate and the flow rate through an auxiliary heat sink such as in the case of a radiant floor heating. In situations where water is in an overheated condition, an auxiliary heat sink can help achieve a specific water temperature output by diverting excess thermal energy to an auxiliary heat sink.

A control output is provided to modulate the flow magnitude through the internal and/or external recirculating flow circuits 25, 27. The placement of pump 28 in the main flow path enables one or both of the recirculating flows.

FIG. 3 depicts a controls diagram for the current invention. It is to be understood that even though not all inputs are shown for each control portion, it is the intent of the inventors that one or more of the omitted inputs may be used in the control system. The current diagram as it is shown represents a simplified controls diagram depicting major control inputs affecting each control portion. The rate of change of each input is also omitted since time domain is inherent in any control systems.

Referring generally to FIGS. 1 and 2, and more particularly to FIG. 3, the outlet water temperature is controlled by varying the output of flow limiting valve 24, primary heating element 9, secondary heating process 17, pump 28 and three way valve 56. Primary heating element 9 represents the heat source provided by the combination of a blower 36 and a burner 34. Controller 38 comprises several distinct control portions. Each control function 90, 92, 94, 96, 98, 100, 102 is depicted in a distinct block diagram in FIG. 3. Each controller 38 within a control portion represents a control methodology responsible for driving one or more hardware components. Each control methodology can include a control method such as a Proportional Integral Derivative (PID) control or a component of this control method such as the Proportional portion, the Integral portion, the Derivative portion or any combination of these components. Each control methodology can also include a fuzzy logic control. The output of each control portion contributes to the water heating rate of the water heater 2 and therefore the outlet temperature 70.

In the exemplary embodiments, the control system includes main control 94 which is responsible for driving outlet temperature 70 quickly towards desired temperature 74. It can be thought of as the control portion that brings outlet temperature 70 to desired temperature 74 at steady state. Main control 94 compares inlet temperature 72 and desired temperature 74 and calculates a corresponding heating control output based on the difference 78 in the inlet temperature 72 and desired temperature 74. Main control 94 also receives a flow rate 80 and calculates a corresponding heating control output based on flow rate 80. In addition, main control 94 takes the differential pressure signal 106 between the inlet and outlet flow as an indication of the presence of a flow. The magnitude of a demand is indicated by the combination of both flow rate 80 and differential pressure signal 106. A small demand is indicated by a differential pressure only, while a large demand is indicated by a combination of a differential pressure as registered on differential pressure switch 104 and a flow rate as registered by flow sensor 26. As flow rate increases, the intensity of burner 34 is increases. Conversely, as flow rate decreases, the intensity of burner 34 is also decreased. Under certain conditions, burner 34 can be turned off. Recirculation is provided and functions to remove residual heat from the heat exchanger.

The control system further includes feedback control 92, which is responsible for mitigating transience and also ensuring that outlet temperature 70 is driven towards desired temperature 74 and meets desired temperature 74. Feedback control 92 compares the desired temperature 74 and outlet temperature 70 and calculates a corresponding heating control output based on temperature difference 76 between the desired temperature and the outlet temperature.

The control system further includes feedforward control 90 which is responsible for mitigating transience and also ensuring that outlet temperature 70 is driven towards desired temperature 74 by applying a heating control output based on outlet temperature 70. Feedforward control 90 receives the outlet temperature 70 and calculates a corresponding heating control output based on the magnitude of outlet temperature 70.

The control system further includes recirculation control 100 which comprises an internal recirculation control and external recirculation control features. Internal recirculation control is primarily used for mitigating transience and aids in mitigating freeze hazards. External recirculation control eliminates the issue related to the cold column trapped between the heater and a point of demand. Additionally, external recirculation functions to reduce delays associated with supplying hot water from the heater to a point of demand. Recirculation is provided by a pump 28 in combination with either internal modulating valve 35 or external 37 modulating valve, and is used when a buffer tank 15 flow exists as permitted by buffer tank bypass three way valve 56. When outlet temperature 70 approaches substantially the merged flow temperature 41 as measured by temperature sensor 39, recirculation is turned on in conjunction with buffer tank 15 to avoid potential overshoot in the situations where flow rate is suddenly decreased or stopped.

The control system 102 further includes a flow limiting valve and an available power 112 calculator, the calculator provides an estimate of available power based on the sum total of the power ratings of each of the system's heat sources. The power requirement is the power required to take the water with a flow rate 80 from an input temperature 72 to a desired temperature 74. If the power requirement exceeds that of the available power calculated by available power 112 calculator; controller 38 calculates a flow rate which would result in a power requirement meeting the available power 112 and controls the flow limiting valve to provide this flow rate.

The control system further includes a buffer tank bypass three way valve 56, wherein the valve provides the ability to meet a user demand in the situation where the temperature at buffer tank 15 or at the outlet is not sufficiently hot. Controller 38 determines whether outlet temperature 70 is high enough to meet a user demand by comparing the desired temperature to the outlet temperature 70 and buffer tank 15 temperature. If the desired temperature is higher than either the outlet or buffer tank 15 temperature, the controller further determines whether buffer tank 15 flow needs to be reduced. If the outlet temperature is larger than buffer tank 15 temperature, the valve port connected to buffer tank 15 will be closed or reduced effectively closing or reducing buffer tank 15 flow and the valve port connected to buffer tank bypass line 45 will be opened or increased in order to divert all or allow larger flow through buffer tank bypass line 45. By bypassing buffer tank 15, all heated water is delivered directly and expediently to first demand point 66 without having been mixed with cooler water in buffer tank 15. As a demand persists, bypass flow 44 will be gradually decreased and buffer tank flow 54 increased so as to increase the ability of the heating system to handle transience as buffer tank 15 will store sufficient heated water to buffer any temperature fluctuations due to a sudden increase or decrease in demand.

FIG. 4 depicts an alternate embodiment of water heater 2 configured to provide hot water for a variety of applications. In this embodiment, water heater 2 is connected to a second demand point 68 via an auxiliary three way valve 59. A second outlet temperature sensor 23 provides water temperature at second demand point 68. In this configuration, heated flow 13 is mixed with inlet flow cold water to achieve a desired temperature specified for second demand point 68. Mixed flow 21 to second demand point 68 is a merged flow of heated 13 and cold water inlet flow. Controller 38 determines the positions of three way valve 59 ports for mixing the correct amounts of heated and cold water to achieve the desired temperature. The need for having an additional water outlet at distinct temperatures is solved by providing a three way mixing valve and a temperature sensor operably connected to water heater controller 38. The temperature to each water outlet is user definable. For example, the water line connected a dishwasher could be set to 140 degrees Fahrenheit while the water line connected to a shower could be set at 105 degrees Fahrenheit and the water line connected to a hydronic heating system could be set at 160 degrees Fahrenheit.

Referring again to FIG. 4, an external auxiliary device circuit 19 is provided. In this embodiment, auxiliary heat sink 64 (e.g. a radiant heat coil), incorporates a modulating valve 47 wherein modulated heated flow 13 is externally recirculated with the aid of pump 28 and returned via internal recirculation flow 32. In cases where cold water column at first demand point 66 is a concern, such external configuration may also be used to recirculate heated water to first demand point 66 placed at great distance from water heater 2. The problem of long delays to get hot water to the first demand point 66 due to cold water being present in the lengths of pipe between the water heater and first demand point 66 is solved by providing pump 28 to enable external recirculation. Additionally, external auxiliary device circuit 19 can be used to introduce heated water into the hybrid tankless water heating system derived from alternate energy sources such as solar energy, geothermal energy, microwave energy, electric energy, or the like.

FIG. 5 depicts another way a heat sink may be connected. In this embodiment, a heat sink such as a radiant heat coil is connected to internal recirculating flow circuit 25. This embodiment provides less flexibility in controlling the heat sink flow since auxiliary heat sink 64 flow is also internal recirculation flow 32.

Now that an exemplary embodiment of the present invention has been described, focus will be turned to a discussion of the novel features and advantages provided. Many drawbacks and limitations of the prior art have been overcome by the present invention.

By placing buffer tank 15 downstream from the primary heat exchanger variations of actual outlet temperature from a desired outlet temperature can be reduced. Referring to FIG. 1, buffer tank 15 receives heated water at its inlet from the exit port of the heat exchanger that is receiving heat from a burner 34. In one mode of operation, the water flowing through buffer tank 15 is delivered to first demand point 66. In another mode of operation, a portion of the water flowing through buffer tank 15 is delivered to first demand point 66 and the remaining portion is recirculated to the inlet of the water heater. The recirculated water is merged with incoming cold water at the inlet, resulting in a flow into the heat exchanger that is at a higher temperature than the incoming cold water. The water temperature exiting the heat exchanger can fluctuate due to variable heat rate provided by burner 34 during operation. When the water flow with fluctuating temperature enters the buffer tank, the incoming flow mixes with the existing buffer tank 15 water, thereby lessening the impact of any sudden changes in temperature of the incoming flow and resulting in water flow that is more uniform over time.

The current buffer tank 15 placement differs from prior art water heater systems where buffer tank 15 is mounted upstream of the heat exchanger. In the prior art configuration, a forced recirculation is necessary to effectively mix a heated flow with the cold incoming water, necessitating the utilization of a recirculation pump. Since buffer tank 15 is placed downstream from the heat exchanger in the current invention, no forced recirculation is necessary to realize the benefit of buffer tank 15 during portions of the water heater operation. Thus, the problem of minimizing variation of actual outlet temperature from a desired outlet temperature in a fluid control system is solved by disposing a buffer tank 15 downstream of the heat exchanger in a fluid heating system.

Another drawback with current on demand water heaters is an undesirable and inconvenient delay for the user to receive water in the desired temperature range. The delay associated with obtaining the hot water at the desired temperature is related to the temperature of the cold water input feeding the water heater. The delay can be attributed to the corresponding heat transfer from the burner to the contained water located within the heat exchanger tubes. A byproduct of the delay results in a user avoiding the cold initial water flow resulting in waste of both time and water. By way of illustration, most users taking a shower will wait to commence use of the water until the temperature reaches (increases to) a certain comfortable range. The flowing water, as well as the user's time, is wasted as the cooler water flows down the drain waiting for the flowing water to reach desired or target temperature.

A second heating source, when placed inside a reservoir of water such as the stored water in buffer tank 15, enables the water heater to quickly meet the sudden increase of a sizable hot water demand by quickly raising the water temperature in buffer tank 15 so that water can be delivered to the user at desired temperature. In one embodiment, an immersion electric heater is used as secondary heating element 16. A secondary heating element 16, e.g. an electrical heating element, transfers heat by conduction to the water surrounding its coil. Unlike a burner-heat exchanger arrangement, the heating source of secondary heating element 16 comes in direct contact with the water and can therefore transfer heat more efficiently to the water.

A second heating source also provides fine heating modulation which is lacking in a primary heating source. Fine tuning the outlet fluid temperature is achieved by providing primary heating element for coarse adjustment to the inlet fluid temperature and further providing a secondary heating element for fine adjustment to the inlet fluid temperature.

Overshoot in outlet temperature response is minimized by providing a secondary heating element 16 with variable heating power at low heating rate, and/or a mixing valve and/or a capillary bypass line 60. By way of illustration, the secondary heating element 16 (e.g., electric heating coil) is used where ambient temperature is over 70 degrees F. Primary heating element 9 (e.g., burner) provides coarse adjustment and secondary heating element 16 provides fine adjustment to the inlet temperature. A decrease in demand causes excess heat stored in the heat exchanger tubes to be transmitted to the fluid due to the temperature gradient favoring heat transfer from the tubings to the fluid. Buffer tank 15 holds ample amount of water to be recirculated in order to dissipate the excess heat once heating has ceased. A mixing valve mixes overly heated fluid with fluid at a lower temperature, quickly reducing a potential overshoot in the outlet temperature to a safe temperature.

Capillary bypass line 60 operably connecting the cold fluid inlet and the hot fluid outlet allows fluid flow from the high pressure side (i.e., cold side) to the low pressure side (i.e., hot side) causing the overly heated fluid to be mixed with the colder fluid.

Delayed temperature response is also minimized by proactively maintaining the outlet temperature during pre-set periods of water usage or predicted periods of water usage. In the present invention, there are set time periods in a day at which the outlet temperature will be controlled to the desired temperature to avoid both firing and transient delays. During these periods, the water will be heated, stored in the buffer tank and recirculated. The user may preprogram periods of a day in which high water usage is expected via user interface 43. The user may also select a mode where the controller, through collection and analysis of water usage data over a period of time, automatically determines periods of high usage and maintain outlet water temperature at desired temperature.

When a water demand detected, delayed temperature response is solved by proactively recirculating fluid for initiating the primary heating element. The rapid detection of a growing demand by differential pressure switch 104 causes burner 34 to turn on even when the flow (say between 0.005 and 0.5 GPM) has not risen above the flow sensor 26 detection threshold (typically 0.5 GPM), thereby shortening the time it takes to achieve the desired outlet temperature.

Current tankless water heaters start controlling to desired temperature by detecting a flow condition. Typically, a minimum flow threshold of 0.5 GPM is required to turn on the burner. If a demand fluctuates above and below the minimum threshold, the water will be heated only during portions of the demand resulting in water temperature not meeting the desired temperature. In order to detect a small flow, a prior art method uses a difference in temperature between the inlet and outlet ports of a buffer tank 15 or the rate of drop of the inlet port temperature and outlet port temperature to indicate a flow condition. The use of this indication may be erroneous since the temperature differential between the inlet port and outlet port of buffer tank 15 does not necessarily indicate a flow demand. Another prior art method to detect that a demand exists in a buffer tank involves sensing the temperature drop in either the inlet port or outlet port. This method often results in erroneous demand indication. Therefore, utilizing these indicators may cause the water heater to warm the tank water unnecessarily.

Typically, a minimum flow threshold of 0.5 GPM is required to indicate a demand to cause the burner to turn on. In prior art tankless water heaters, since water is heated only when the minimum flow threshold is met, there will be no heating when the flow demand does not rise above the minimum threshold. This flow condition below the minimum threshold is called the dead zone. In the present invention, a small flow is detected using a differential pressure switch 48, wherein the switch is capable of detecting a flow greater than 0.005 GPM. The detection of a small flow causes secondary heating element 16 to turn on, thereby keeping the outlet water warm. Thus, the problem of dead zones is solved by utilizing a differential pressure switch capable of detecting a small flow for initiating a heating element.

Variance between desired outlet fluid temperature and actual output fluid temperature is reduced by providing supplemental heat via a secondary heating element 16. The need to respond quickly to a hot water demand causes the controller to fire the burner at high rate in order to meet a heating demand. Firing the burner at high rate causes water to warm up quickly. However, the heat exchanger tubing material can store excess heat and reach a high temperature. When the desired temperature is about to be reached, the burner is turned off to avoid or reduce outlet temperature overshoot. If the burner is turned off too early, the outlet water temperature will not reach the desired temperature quickly. If the burner is turned off too late, the risk of overheating the water is greater. Even after the burner is turned off, the excess heat stored in the heat exchanger continues to cause a positive temperature gradient between the heat exchanger tubes and the water flowing through them, thereby causing the heat exchanger to maintain the previously induced burner heating rate even while the burner has now been turned off. If the outlet water temperature can no longer meet the desired temperature, the burner is again turned on. This frequent turn-on and turn-off of the burner causes the undesirable phenomenon called hunting, i.e., the outlet temperature fluctuates about the desired temperature even in steady state. With the use of secondary heating element 16 (e.g. electric heating element) in conjunction with burner 34 (primary heating system 8), water heater 2 can react quickly to a water demand by firing burner 34 to heat the inlet water quickly while reducing overshoot. Secondary heating element 16 is capable of providing a small heat rate that complements the heat rate produced with normal burner 34 operation and pulse firing of burner 34. Secondary heating element 16 minimizes the need for burner 34 to take the outlet temperature very close to the desired temperature before turning off and thereby overcomes temperature overshoot. The problem of excessive heating control hunting especially during periods of trickle or low flows is solved by providing a secondary heating element 16 or pulse firing of primary heating element 9 for fine control of outlet fluid temperature and a means for selecting whether to initiate primary heating element 9, a secondary heating element 16, or combinations thereof.

In prior art water heater systems, a cold sandwich effect occurs when a user briefly turns off a faucet that has been running water of desired temperature for an extended period of time. This brief cessation of demand creates a column of scalding hot water resulting from excess heat transferred to the small quantity of water remaining in the water heater from the heat exchanger thermal mass upon shutting down burner 34. Responding to this high outlet temperature, the controller ceases to provide more heat to the water causing a trailing column of water to be under heated. Eventually when the outlet temperature sensor starts detecting this cold water column due to a resuming demand, heating resumes and a steady state flow with desired temperature is achieved. The problem of the cold sandwich effect in a transient system is solved by recirculating the small quantity of water remaining in the heat exchanger upon cessation of a demand via the buffer tank. Recirculation causes excess heat to be dissipated and distributed more uniformly throughout the remaining volume of water in the water heater. When a demand restarts, recirculating via buffer tank 15 causes the colder incoming water to be mixed with existing warmer water in the buffer tank to yield water at more uniform temperature over time.

Legionnaire bacteria grow well in stagnant water of from 80 to 120 degree Fahrenheit. Recirculation of outlet flow and maintaining water temperature at elevated temperature of 140 deg Fahrenheit aids in eliminating this dangerous bacteria. In the current invention, the water heater can be programmed to turn on periodically. Recirculation causes heat sources to turn on in order to maintain the outlet temperature at the desired temperature. Thus, the problem of bacteria growth in stored water supplies and water system components is solved by recirculation of outlet flow and maintaining water temperature at elevated temperature of 140 degrees Fahrenheit.

In the current invention, an unconventional heat exchanger is used. The burner 34 is inverted and placed above the heat exchanger tubes in a burner cavity. When the fuel supply line is opened, the blower blows air-fuel mixture down towards the heat exchanger disposed below the blower nozzle. As such, the flue gas has the tendency to rise and it must be forced down towards the heat exchanger by a blower. The heat exchanger is an array of tubes where the heat provided by burner 34 is transferred to the water flowing in the tubes. The heat exchanger is configured such that the exiting water flow portion is disposed closest to burner 34 and the incoming water flow portion is disposed most distant from burner 34.

Prior art tankless water heater systems do not provide for an alternate power source during primary power outage. In the current invention, an alternate power source is provided and automatically sourced should a primary power loss to the water heater system occur. Thus, a preferred embodiment provides and automatically sources a secondary onboard energy source such as a backup battery or an inline hydro generator capable of generating electrical power from hydraulic power. By continuously providing power to the water heater in the event of a primary power loss, freeze protection is provided, giving enough time for the user to either drain the water heater system or provide additional and continuous backup power. In addition, continuous operation of the water heater system also allows for temporary hot water usage.

The problem of overheating (temperature spikes) of water during a rapid reduction (step down and completely off) in demand is solved by actively recirculating the water, cutting down heat input, and in some cases by turning the blower to a maximum speed without flame. This is achieved by detecting a change in flow demand, starting the recirculating pump, lowering or shutting off firing of the burner and turning on the blower. Thus, transient temperature spikes are reduced by means of controlling a blower that can optionally operate independent from the burner and a recirculation pump.

In the current invention, detection of a leakage between the water inlet and water outlet of the water heater is accomplished with a moisture sensor that alarms when excessive moisture is detected in the cavity of the fluid heater inside the water heater enclosure. This sensor is capable of sensing a leak that occurs within the water heater enclosure.

In the current invention, leakage from external plumbing operably connected to the water outlet is detected and/or ceased by providing a differential pressure switch operably connected to the inlet end and outlet end of the water heater. This differential pressure switch detects a small flow condition by registering a pressure differential between the two ends of the water heater over a period of time. If this period exceeds a preset leak time threshold, a leak condition is raised and a warning is issued to the user and/or the flow control valve is moved to the closed position.

In the current invention, a small leak or an open faucet for long periods of time will be detected via a pressure difference as registered by a pressure differential switch over an extended period of time as specified by the user. For example, a continuous detection of a pressure difference over a period of 30 minutes may indicate a leak.

In the current invention, detecting leakage downstream of the flow sensor is achieved by providing a flow sensor to detect the actual amount of flow and compare such actual amount of flow to a known quantity of water programmed to be delivered such that when the difference exceeds a predetermined fault threshold, a leak condition is raised. Upon detecting a leak condition, a warning is issued to the user and the flow limiting valve is shut to stop further water loss.

Freeze hazards are minimized in the present invention by periodically maintaining water temperature at a level higher than the freezing point. The current invention periodically recirculates flow even without an external user demand. This recirculation may occur at preprogrammed or learned usage periods and monitoring the heater inlet and outlet temperature or their rate of change such that when the outlet or inlet temperature drops below a certain threshold, or if the rate of temperature drop exceeds a certain threshold, recirculation and/or a secondary heating element 16 is initiated. Similarly, when the outlet or inlet temperature drops below a certain threshold or if the rate of temperature drop exceeds a certain threshold, a secondary heating element 16, combined with pulse firing of primary heating element 9, as well as recirculation, are initiated.

Detecting trickle flow or low flow at any given time is accomplished by using a differential pressure switch. A differential pressure switch is operably connected to inlet 10 and outlet 12 ends of the water heater. The switch is in the off position when there is no flow in the water heater. A flow in the water heater creates a pressure differential between inlet 10 and outlet 12 ends, thereby moving the differential pressure switch to the on position. The pressure differential switch is preferably capable of detecting flow greater than 0.005 GPM or a range of flow not detectable in a flow sensor.

Prior art buffer tank 15 temperature based water heater control systems rely on the temperature difference between buffer tank 15 inlet temperature and buffer tank 15 outlet temperature to indicate a need to turn on a heat source. In the present invention, the entire range of flow demand is detectable by using the differential pressure switch and the flow sensor. Since the temperature difference between buffer tank 15 inlet and outlet is not required, only one temperature sensor is required for buffer tank 15, provided that inlet buffer tank 15 flow is mixed well to yield a uniform water temperature throughout buffer tank 15. This provides an advantage over the prior art using multiple temperature sensors in the controls scheme. Temperature variations within buffer tank 15 are minimized by having baffles or a barrel-hole style inlet system for creating turbulence which promotes mixing of the incoming water with existing water in the tank, enabling the use of a single temperature sensor representative of the entire buffer tank 15 temperature.

In the prior art, the need for a forced recirculation is indicated by a drop in the buffer tank inlet temperature. In this prior art configuration, heating is tightly coupled with the presence of a recirculating flow and heating would not occur until force recirculation has been activated. In the present invention, no forced recirculation is necessary to initiate heating. When a demand exists as indicated by the differential pressure switch and the flow sensor, a high firing rate of burner 34 combined with recirculation, meets the hot water demand in a short time without having to unnecessarily warm water stored in buffer tank 15 for an extended period of time. Thus, the problem of long duration necessary to heat up water to the desired temperature is solved by actively recirculating the water and by deliberately increasing the heat input (higher firing rate) for a predetermined duration upon detecting a flow demand. This provides a significant advantage over the prior art since temperature control is enhanced during transience and startup flow conditions.

In systems relying on the water temperature in buffer tank 15 as a leading indicator to trigger heating, much of the heating is wasted when there is no actual demand. However, with a system relying on the differential fluid pressure between the inlet and the outlet ends and flow sensor to indicate demand, heating would commence only when there is an actual flow unless it is programmed to do so otherwise. Also, temperature is a lagging indicator in that it takes longer for temperature to change to indicate a change in demand whereas a heating system based on the presence or magnitude of a flow indicates a change in demand immediately so that this change can be acted upon immediately thereby improving the heating response time. Thus, the goal of maintaining outlet temperature is achieved by using a differential pressure and a flow rate as leading indicators in the present invention.

When hot water is first requested, a motorized three way valve closes the flow path to the buffer tank, thereby bypassing it and diverting all heated water to the point of use. As the burner keeps up, the three way valve slowly diverts the flow through to buffer tank 15 and maintains a portion of the flow in the bypass line. Thus, the long duration necessary to heat water to the desired temperature is eliminated by bypassing the buffer tank 15 during startup and increased demands so that undiluted hot water can be delivered to the point of use without having been mixed with cooler water in the buffer tank.

Water hammer occurs when a user suddenly ceases water demand by closing a valve creating pressure surges. A capillary bypass line 60 can absorb the pressure surges, mitigating the damaging effects of water hammer. Thus, the problem of high pressure spikes is minimized by using a dedicated capillary bypass line 60 operably connected to the inlet and outlet ends of the water heater.

The minimum power output of burner 34 is typically 20,000 BTU/hour (with a modulation range of 10:1 (turn down ratio) and a burner size of 200,000 BTU/hour). In order to achieve a lower average power output, pulse firing is used. In pulse firing, the burner power is modulated such that in a pulse cycle, burner 34 is turned on for a preset duration and turned off or turned down to a lower setting for another preset duration. The average power is the average power of each cycle. Thus, the problem of inadequate low firing rate or minimum firing rate constraint is solved by pulse firing burner 34 (with constant blower operations).

As the water heater ages, various components of water heater 2 may break down and require repair or replacement to ensure proper operation of water heater 2 and to avoid safety hazards. Scaling may develop in the interior surfaces of the flow tubes of water heater 2. Inadequate recirculation can be a sign of pump breakdown. The ability to detect a failed pump is provided by detecting excessive flue temperature and flue temperature rise rate. This provides a significant advantage over the prior art. A service alert can be issued when such a condition is detected. Thus, pump failure or inadequate recirculation flow is detected by monitoring the flue out temperature and its rate of change to proactively managing the heat input (e.g., powering off the unit). Additionally, the problem of degraded heat exchanger performance is detected by monitoring the flue out temperature and its rate of change, buffer tank or outlet water temperature to proactively inform user to intervene. Under normal operation, the heat provided by the burner is properly transferred to and absorbed by the water flowing through the water heater. Since a good portion of provided heat is recovered, the flue gas temperature should not be excessively high. The flue vent material is protected by monitoring the flue gas temperature and its rate of change to proactively manage heat input.

Most modern water heaters are designed without providing the user or service personnel serviceability. Poorly maintained water heater may need to be replaced prematurely. In the present invention, serviceability is facilitated. Hard water causes unwanted mineral deposits (scaling) on the fluid contact surfaces of the water heater system. Severe scaling can cause severe drop in the water heater efficiency and life span. Scale deposits in the interior surfaces of heat exchanger tubes can reduce the heat exchanger efficiency as the scale deposits reduce heat transfer rate from the exterior to the interior surfaces of the heat exchanger tubes. Therefore, more heat would be required to raise each degree of water temperature. Excessive scale deposits, or any other like issues, that cause reduced heat exchanger efficiency, can lead to overheating of the exterior surfaces of a heat exchanger resulting in a shortened heat exchanger service life. In addition to resulting in damage to the heat exchanger, overheating of the heat exchanger exterior surfaces leads to undue energy loss. The problem of overheat and heat loss of the exterior surfaces of heat exchanger is solved by providing at least a baffle or a structure capable of swirling or mixing pre-combusted air (as provided by blower 36) in the vicinity of the heat exchanger, thereby promoting heat transfer from the exterior surfaces of the heat exchanger to the pre-combusted air and recovering this absorbed heat of the pre-combusted air by redistributing it to colder portions of the heat exchanger surfaces.

There is provided a service access to the hot water system such that a cleaning agent may be introduced in the recirculating flow circuit and a dedicated service mode such that the recirculation pump may be activated without turning on any heat sources. The prior art does not provide end-user direct access such as this, rather, requires a trained maintenance person to perform such tasks by at least partially taking apart the water heater.

When a problem occurs, a typical water heater diagnostic system provides rudimentary information in the form of fault codes which require further decoding for corrective instructions. A novel feature of the current invention enables an end user of the current water heater to take appropriate steps by providing not only fault codes but also corrective instructions associated with the fault codes. As such, the end user is capable of taking corrective actions without having to wait for service personnel or resort to an instruction manual. In one embodiment, a fault code is decoded by providing speech capability to the water heater, a means of transmitting a spoken fault code by phone to a fault code database, a means for identifying the problem source and its associated corrective procedures based on the transmitted fault code and a means for notifying the user of the corrective instructions. In another embodiment, a fault code is decoded by automatically transmitting a fault code via internet to an off-site database, retrieving corrective instructions based on this fault code, and notifying the user of corrective instructions with text or audible speech instructions.

In the current invention, active and continuous monitoring performance and health of the water heater minimize unforeseen service outages. In one aspect, the controls provide for automatic adjustment of operating parameters based on measured performance. Performance is determined by logging blower rpm, power output and comparing them to nominal values and the water heater's historical data. Additionally or alternatively, prognostic feedback is provided to the user so that a water heater problem can be responded to before a break down can occur. In the event a problem is so severe that it cannot be corrected automatically, the user is timely alerted.

In a condensing heat exchanger, a drip collection pan is used to collect the condensate which is in turn drained with or without pressure assist via a drainage tube to a sump. A blockage in the drainage tube can cause backup or overflow of the condensate and cause corrosion in water heater components exposed to this condensate. A condensate level sensor 50 provides alert and calls attention of the user that condensate drainage is blocked and requires attention. A small pump may also be used to aid condensate drainage. In the case a small pump is used, the need for gravity drainage is unnecessary and therefore the need to mount the water heater at an elevated position to create this gravity drainage is eased. Thus, the problem of flue condensate backup or blockage is detected by using condensate level sensor 50.

Flow sensor 26 as used in this invention is connected to the inlet of the water heater and therefore does not experience elevated temperature. As such, it does not require a more expensive high temperature grade flow sensor. By mounting the flow sensor outside of the recirculating flow circuit, there is no pressure loss imparted by the flow sensor. This allows the use of a pump with a lower power rating, thereby making the water heater more economical. Additionally, no proprietary valves are required.

When a user first enters a shower, the user may be initially satisfied with a water temperature that is higher than the ambient air temperature. The user will likely demand progressively hotter water as the shower progresses due to user temperature acclimation. Normally, a user demands hotter water by manually increasing the valve controlling the hot water supply. The present invention optionally includes a feature that allows the user to set an automatic temperature rise rate and a high temperature limit that aligns with the user's temperature rate of change profile or acclimation profile; thereby providing a varying temperature service. For example, the initial requested temperature is 90 degrees. The user may choose to increase the water temperature by 1 degree per minute. If the demand is left untouched, the water temperature would be increased to 95 degrees in 5 minutes of usage. If the high temperature limit is set at 92 degrees, the water temperature would be increased only to 92 degrees in 2 minutes and remains at that temperature throughout the rest of the duration of the demand.

Automatic faucets have been in widespread use for some time. In an automatic faucet system, a proximity sensor is used to detect the presence of a demand. When a user approaches the faucet with his or her hands extended into the field of view of the proximity sensor, the faucet is automatically turned on and water is automatically discharged. This will trigger external or even internal recirculation, thus “preparing” the water heater to be ready for anticipated water use. Proximity sensors here are used to detect the presence of a person in the bathroom, sending a signal to the heater and preparing the heater for hot water use.

Natural gas is an energy source or fuel commonly used in residential homes, businesses, as well as industrial settings, appliances and systems that operate on natural gas include HVAC systems, kitchen stoves, clothes dryers, water heaters, and the like. The number of natural gas devices that can be powered simultaneously is a function of the utility natural gas service line(s) maximum capacity compared to the sum of the gas usage rates of the individual devices. A natural gas over-demand situation occurs when the cumulative sum of usage rates from each of the operating natural gas appliances or devices is greater than the maximum capacity of the incoming natural gas service utility line or lines. During such a natural gas over-demand situations, it's common to engage a device's fail-safe system. System fail-safes include flameout or other type of natural gas shut down type routines resulting from inadequate natural gas supply or gas starving.

In one embodiment of the present invention, the undesirable gas over-demand type situations are avoided or reduced in frequency in hybrid tankless water heating systems by utilizing a modulating gas burner where the natural gas consumption rate is reduced, or de-rated. This reduction is accomplished via the modulation of a modulating gas valve and cooperating blower. Controlling the heater in such a manner, results in the reduction of natural gas usage or consumption rate and associated reduction in blower speed by predetermined levels dictated by a controller. The typical hybrid tankless water heating system includes a blower, a burner, and a buffer tank having an auxiliary heating means having an energy source other than natural gas along with supporting hardware. Supporting hardware includes at least one natural gas pressure sensor, can be a hardwired element as well as a wireless version, that is located upstream or in the gas feed line of the hybrid tankless water heating system, and a controller to enable cooperation among the various system elements. Alternatively, a network of gas powered devices can relay their status including usage rates to a controller thereby creating an alternate embodiment without the need for a natural gas pressure sensor (since available gas capacity can be calculated).

In a typical configuration, the natural gas pressure sensor is used to determine the real time natural gas available to the hybrid tankless water heating system, and in conjunction with a controller, is used to detect a natural gas over-demand situation. If such a natural gas over-demand situation is detected or predicted, the controller reacts by de-rating the burner and blower subsystem of the hybrid tankless water heating system. Given a particular natural gas input line geometry (e.g. round pipe inner diameter); maximum flow rates are easily calculated along with corresponding heat output.

Another variation of the present embodiment under discussion is the use of two or more external gas usage sensors or monitors each having an input signal to the controller that provides an indication as to whether or not the gas supply is shared among gas consuming appliances, enabling the calculation of the real time gas supply rate available. If it is determined that the utility natural gas service line is shared by one or more gas consuming appliance, the water heater burner will be de-rated if a natural gas over-demand situation is detected or predicted by limiting the gas valve opening to align with the actual gas supply available at that moment. By having a more accurate burner heat output prediction, the controller is better able to determine whether supplemental heat via the buffer tank to compensate for the reduction of natural gas should be used. In one embodiment, the external gas usage input receives gas pressure sensor measurement from the gas supply line. In another embodiment, the controller wirelessly receives one or more signals indicating the corresponding pressure drop, usage rates, or the like of the other appliance(s) sharing the same gas supply line.

The typical method for reducing natural gas consumption in a hybrid tankless water heating system to avoid a natural gas over-demand situation comprises continuous monitoring of available natural gas pressure along one or more portions of the natural gas distribution network monitoring for potential natural gas over-demand situations. If such a natural gas over-demand situation is detected, a controller reduces the burner natural gas consumption rate and speed of the corresponding blower by predetermined levels such that natural gas consumption rate of the hybrid tankless water heating system avoids the undesirable natural gas over-demand situation.

The following example provides a more detailed analysis of one embodiment. The embodiment includes a modulating gas burner wherein the supply of gas is modulated by adjusting a modulating gas valve connected to the modulating gas burner. Referring again to FIG. 2, there is further provided an external gas usage input signal 53 which corresponds to the rate at which the gas supply is used by external gas consuming appliances such as a furnace. In a typical operating environment, there may be multiple gas consuming appliances, such as a gas furnace, radiant floor heater and water heater burner which source gas from the same gas supply. If all appliances are operating at their respective high or maximum capacities, a condition may exist where the gas supply is incapable of supplying gas to all appliances at normal operating pressure. Under such condition, one or more appliance is said to be starving for gas wherein the actual gas supply rate is below the expected amount. There exists a need in modulating gas supply to the current burner such that the heat output corresponding to the gas supply is quantifiable. The external gas usage input signal 53 provides an indication as to whether or not the gas supply is shared amongst gas consuming appliances and/or what gas supply rate is available. In one embodiment, such indication is provided by a gas pressure reading that is lower than a predetermined level. Upon determination of a shared gas supply, the water heater burner will be derated by limiting the gas valve opening to better reflect the true heat output corresponding to the gas supply. By having a more accurate burner heat output prediction, the controller is better able to determine whether supplemental heat is necessary. In one embodiment, the external gas usage input receives gas pressure sensor measurement from the gas supply line. In another embodiment, the external gas usage input receives a signal indicating the rate or the presence of gas usage of a second appliance sharing the same gas supply. In one embodiment, the external gas usage input is received wirelessly.

When a hybrid tankless water heating system is initially turned on or when a water demand is abruptly increased, there is an initial warm up period where the burner-blower subsystem has to get the heat exchanger up to a temperature that will yield output water flow at the target predetermined temperature. During this warm-up period, if hot water is requested, the temperature of the output water flow will be lower than the desired target predetermined temperature, thus creating undesirable cold water transient.

In one embodiment of the present invention, the length of time or duration associated with undesirable cold water transient is reduced by the incorporation of a water flow limiting valve and a controller functionally connected to the water flow limiting valve. This is accomplished by restricting the water flow through the hybrid tankless water heating system or water heater, thereby enabling the delivery of water at the predetermined temperature at a reduced flow rate. Supporting hardware includes at a minimum, an output temperature sensor located at the output of the hybrid tankless water heater for measuring an output temperature, an input temperature sensor located at the input of the hybrid tankless water heating system for measuring an input temperature, a flow sensor for measuring a flow rate requested of said hybrid tankless water heating system and a controller for determining an operating capacity corresponding to the difference between the predetermined temperature and the output temperature, the difference between the output temperature and the input temperature and the flow rate. As a demand capacity increases abruptly, the flow limiting valve is restricted to reduce flow rate such that the output water predetermined temperature is quickly achieved. As the water heater's operating capacity becomes more readily available, the setting of the water flow limiting valve is adjusted such that higher flow is permitted while the output water is maintained at the predetermined temperature.

An example of the aforementioned flow rate follower function is described in the following sample scenario having a given input or inlet water pressure. In this example the target water flow is 5 GPM at predetermined target temperature. Initially, the water flow limiting valve is set to a predetermined position that is less than its maximum setting, to enable a predetermined flow rate of 3 GPM. As the water heater output temperature nears or attains a steady state condition, the water flow limiting valve gradually opens allowing additional water flow. This occurs as a result of the burner-blower subsystem heating the heat exchanger up to a temperature, or thermal capacity that is capable of delivering output water at a higher flow rate at the predetermined target temperature. An initial flow represented by t=0 is set at 3 GPM. Then at time t=1, the valve opens further to allow flow up to 4 GPM (valve restriction is decreased to allow more flow). Finally at time t=2, the flow is increased to 5 GPM (valve restriction ceases allowing full flow). It is understood that steady state conditions are achieved at both t=1 and t=2 time intervals. This allows for the heat exchanger-burner blower system to catch-up to the heat demand while maintaining the desired outlet temperature since the burner cannot instantly achieve the desired thermal output.

Recirculation alone, or recirculation combined with heating, may also be used prevent freeze and may be activated with or without the detection of a flow. Recirculation and/or heating may also be programmed to start at a user-specified regular interval for a user-specified duration using a timer, or the like. Alternatively, the program may be adapted to “learn” users' hot water usage behavior to better anticipate periods of use. In a present adaptive control system, water usage data such as time stamps indicating the starting and ending points of a requested flow and the volumetric flowrate of a flow request, are collected over time and analyzed. As a result, recirculation and/or heating can be automatically turned on to anticipate periods of high demand. In addition to providing freeze prevention, automatic activation of recirculation and heating minimizes delays of temperature response to a demand.

In a typical residential or commercial water heater installation, heated water is typically requested according to daily activities of its users. For instance, in a residential installation, heated water is not commonly requested during normal business hours and during the night as the users of the installation are typically not home during normal business hours and at sleep during the night. Conversely, in a commercial installation, heated water may be mostly requested during business hours as workers or guests are present during such hours. Commercial installations may also experience larger usage discrepancies between a certain day of a weekday and a weekend day. As heated water use can be sporadic in many instances, a fixed program for anticipating and preparing for such use is undesirable as unused heated water returns to ambient temperature due to heat loss to its surroundings, leading to wastes. Therefore a control system that is better suited at predicting usage based on past usage history is desired. In accordance with the present invention, there is provided a water heating control system which anticipates water usage throughout the 24-hour daily cycle and prepares the water to meet such usage and reduces delay in delivering a volume of water at a flowrate where the volume of water is heated from a first temperature to a target temperature during a time interval 114 of a day.

The water heating control system comprises:

-   -   (a) a device for aiding in heating the volume of water at the         flowrate from a first temperature to a target temperature;     -   (b) a historical flow demand corresponding to a time interval of         a day;     -   (c) a current flow demand corresponding to the time interval of         a day; and     -   (d) a controller configured for calculating a new flow demand         from the historical flow demand and the current flow demand,         wherein if the new flow demand exceeds a threshold, the device         is configured to be activated during the time interval of a day         and the new flow demand is configured to be set as the         historical flow demand for the time interval of a day.

The device can be an internal recirculating flow circuit 25, an external recirculating flow circuit 27, a burner 34, a burner 34 and blower 36 combination, a valve 35, 37, 47, 56, 59, a pump 28 and any combinations thereof or another water heating aid. The operations of each of these devices have been described elsewhere herein.

In one embodiment, the current flow demand is the current flowrate (CF) of the requested heated water. In one embodiment, CF is used to determine flow usage indicator (FUI). FUI can be viewed as a parameter indicating whether or not the current flow is critical to be considered in determining the present decision to activate a heating aid. For example, if CF is greater than a first threshold (e.g. about 0.5 GPM) for more than about 5 minutes, then FUI is set to 1. If CF is about 0.5 GPM or less, then FUI is set to 0. In one instance, flow sensor 26 data is used to collect CF data.

The historical flow demand can be any one of the following items or any combinations thereof:

-   -   (a) historical average flowrate (HAF) 120;     -   (b) historical average flow volume (HAFV);     -   (c) historical average frequency of flow request (HAFFR); and     -   (d) historical average frequency of user presence detection         (HAFUPD).

In one embodiment, in determining HAF, the magnitude of a flowrate and the duration in which this flowrate is sustained at such magnitude are contemplated. For instance, in order to consider the heating requirement of a flow, the flowrate must be maintained at above about 0.5 GPM for at least about 5 minutes. In another embodiment, the magnitude of a flowrate alone is used to determine whether the flowrate is considered in determining HAF.

If flow volume is used instead, the volume of heated water requested during a time interval determines whether a heating aid is to be activated. The volume of heated water request is a function of the flowrate (or magnitude of flow per unit time) and the duration at this flowrate. For instance, in order to consider the heating requirement of a flow, the flow within a time interval must total no less than 10 gallons.

The frequency of flow request is defined as the number of times a flow exceeds about 0.5 GPM and subsequently drops below about 0.3 GPM during a time interval of a day. A higher frequency translates to an increased amount of activities and therefore an increased need to anticipate and prepare hot water.

A user presence detection, as used herein, is defined as an event corresponding to a water heater pre-activation signal wherein the detection of which is made according to teachings of the Applicants' copending application, U.S. Pat. Pub. No. 2011/0042470, which is hereby incorporated by reference in its entirety. The frequency of user presence detection is then defined as the number of user presence detections within a time interval of a day.

The new flow demand is configured to be calculated by applying a first weighting factor (WF1) to the historical flow demand to result in a first intermediate result and by applying a second weighting factor (WF2) to the current flow demand to result in a second intermediate result. WF1 and WF2 are tunable parameters. In one embodiment, WF2 is a complementary percentage of the first weighting factor. For example, if WF1 is 0.8, WF2=1−WF1=0.2. Applicants discovered that by providing the sum of the first and second weighting factors as unity, the contribution of the current flow demand as opposed to the historical flow demand can be more easily tuned as the increase of one has a direct effect of a decrease in the importance of the other. Applicants also discovered that a time interval of about 15 minutes provides sufficient resolution to typical residential and commercial applications.

Assuming that HAF is used as the historical flow demand, the new flow demand (NFD) is provided below: NFD=WF1*HAF+WF2*FUI  Equation 1

FIG. 6 is a table depicting an example of the flow data during three time intervals 114 of a day, i.e., 12:00-12:15 am, 12:15-12:30 am and 12:30-12:45 am. In practice, this table is extended to cover the entire 24-hour period of a day. However, only three time intervals are demonstrated in this example for purposes of clarification. FIG. 7 is a table depicting an example of the flow data during a time interval of a day for ten days (from Day 1 to Day 10) for the time interval of 12:00-12:15 am (or 15 minutes). It shall be noted that the data associated with “Day 4” of FIG. 7 is the data depicted on line “12:00-12:15 am” of FIG. 6. In practice, the data critical to the calculation for a current time interval is the same time interval of the day prior to the current day. Referring back to FIG. 6, the table lists the time intervals on the left most column. Various pieces of data including the current flowrate (CF) 116, flow usage indicator (FUI) 118, average flow 120 and recirculation trigger 122 are shown. The recirculation trigger column represents whether or not an action (i.e., recirculation in this case) is to be taken automatically within a time interval to reduce the amount of time it takes to heat water if a heated water request becomes a reality.

For example, according to Equation 1, the NFD of Day 5 is calculated as follows: Day 5: NFD=0.8*0.36+(1−0.8)*1=0.49 where WF1=0.8, FUI=1 as CF is greater than about 0.5 GPM. The NFD of about 0.49 at Day 5 now becomes the HAF of Day 6. Therefore the NFD of Day 6 is calculated as follows: Day 6: NFD=0.8*0.49+(1−0.8)*1=0.59

In order to determine whether a heating aid should be turned on, the NFD is compared to a second threshold. In the example of FIG. 7, the second threshold is set at 0.3. As the NFDs of both Day 5 and Day 6 are greater than 0.3, the recirculation trigger are both set to 1, i.e., “On.”

Referring back to FIG. 7, it shall be noted in the present adaptive control system that as historical heating demand is considered, the decision to turn on recirculation hinges not only upon the current data but also the historical data. Notice on Day 7 that although the CF is about 0.4 GPM, a value under the first threshold of about 0.5 GPM and therefore an FUI of 0, the flow average remains relatively high, due largely to the flow average magnitude from the flow average of the previous day, thereby still causing the recirculation trigger to indicate a need to turn on recirculation on Day 7. The same need for recirculation continues for two more days until Day 10 where the consistently low flow requests of Days 8, 9 and 10 at about 0.3, 0.4 and 0.1 GPM respectively, cause recirculation to cease on Day 10. By the same token, recirculation does not commence immediately upon the detection of a current flow sufficient to indicate that it should be considered. For instance, the current flow of about 0.6 GPM on Day 3, a flow request having a flowrate exceeding the first threshold, does not cause recirculation to turn on as the flow average is a function of the historical flow average that was 0 from the prior day. As the current flow remains high on Day 4, the flow average on Day 4 of about 0.36 GPM becomes sufficiently high to cause recirculation to be turned on. The present adaptive heating control system therefore has the ability to “learn” the most likely heated water request during a particular time interval and turns on one or more appropriate heating aids at the start of the time interval.

Assuming that HAF, HAFV, HAFFR, HAFUPD are used as the historical flow demand, the new flow demand (NFD) is provided below: NFD=WF1*HAF+WF3*HAFV+WF4*HAFFR+WF5*HAFUPD+WF2*FUI  Equation 2 WF3, WF4 and WF5 are additional weighting factors where weighting factors WF1-WF5 preferably add up to unity such that the effect of a trending change in one weighting factor is conveniently related to an opposingly trending change in one or more other weighting factors.

In carrying out adaptive heating control, any historical data is preferably saved in a non-volatile memory 124 such that it may be accessed in the same time interval of the next calculation cycle (day). Referring back to FIG. 2, the controller is responsible for receiving any necessary data such as flowrate from the flowrate sensor 26, time data from its clock 126 and making any calculations related to Equations 1 or 2 to result in an NFD. The NFD is then compared to a threshold and if NFD is greater than the threshold, the device is activated.

FIGS. 8 and 9 are sample water usage of a 300-room hotel on a weekday and a weekend day, respectively. FIG. 10 is a sample water usage of the 300-room hotel of FIG. 8 on another weekend day. The abscissa of each sample represents the time stamps of day while the ordinate of each sample represents the magnitude of hot water demands. It shall be noted that from these samples that, the usage can vary widely (in frequency and magnitude) from one time interval to another time interval within one day. In addition to varying from one time interval to another time interval within one day, the usage can also vary from one day to the next. If such patterns can be observed to be dependent upon the day of a week, the present adaptive control system may be applied to a series of a day of a week such as Monday of week 1, Monday of week 2, Monday of week 3 and so on instead of Monday of week 1, Tuesday of week 1, Wednesday of week 1 and so on.

FIG. 11 is another embodiment of a hot water heating system of the present invention, depicting a variable volume holding tank used in conjunction with the present adaptive control system. The advantages of an adaptive control system become apparent when used in delivering heated water to demands that fluctuate over time intervals of a day but also where a pattern may be established either between time intervals of a day or days of a week or days of a month. In most commercial water heating applications, a certain volume of water is heated in anticipation of demands within a time interval such that hot water may be provided at sufficient rates. The present variable volume holding tank is essentially a large tank capable of holding sufficient water for extreme demands. However, a typical demand calls for a volume that is less than that of the maximum volume that the holding tank is capable of holding. Therefore, if the holding tank is filled to its maximum capacity for anticipating a demand that does not materialize, energy would have been unnecessarily spent as heat dissipates from the holding tank.

U.S. Pat. No. 6,938,581 discloses a water heater system that provides increased capacity without large additional energy usage. Such a system still requires a supplemental water tank and related hardware, thereby leading to additional equipment and maintenance costs. The present variable volume holding tank however, takes advantage of the use of an adaptive control system in combination with a drain valve for making available a suitable amount in the variable volume holding tank. In use, the adaptive control system first “learns” the usage habits of a residential or commercial establishment. During this “learning period,” the variable volume is filled to its maximum capacity as the adaptive control system does not possess a usage history to justify a reduced fill. As usage habits are established, the amount of water to be heated during a time interval is determined. While transitioning from one time interval to the next when usage habits are being learned, if the expected volume in the next time interval is less than the amount currently held in the variable volume holding tank, the depleted hot water that occurs within the current time interval may not be replenished to anticipate the decrease in the expected usage within the next time interval. If prolonged reduction in demand is expected over multiple upcoming time intervals, a portion of the currently held water in the holding tank may be drained via the drain valve 142 such that a smaller amount of hot water will need to be maintained, thereby reducing the energy usage required for maintaining a larger volume of water at a particular temperature. Referring back to FIG. 11, the variable volume holding tank 128 is essentially a tank within which a variable amount of water may be stored and the tank is disposed at a downstream location of the primary heating system 8 but upstream of first demand point 66. As flow sensor 26 measures the input flowrate to the water heater and flow sensor 130 measures the output flowrate, the difference between the outputs of the two flow sensors 26, 130 indicates the volume of water held in the variable volume holding tank 128. Volume 134 is the air space above the volume of water held 136 in the holding tank 128. An air valve 132 is disposed at a top wall of the holding tank 128 and in connection with the air space 134 while a drain valve 142 is disposed at a bottom wall of the holding tank 128 and in connection with the volume of water held 136 in the holding tank 128. A recirculation line 140 connects the volume of water held 136 in the holding tank 128 to the primary heating system 8. Without a demand at first demand point 66, water may be added via input line 138 when the pump 28 is turned on and the air valve 132 opened. In order to add heat to the volume of water held 136 in the holding tank 128, the primary heating system 8 and the pump 28 are turned on and valve 35 is opened to effect a recirculation flow in the recirculation line 140 in the direction indicated by direction 144. In order to reduce the water volume held 136 in the holding tank 128, the drain valve 142 and the air valve 132 are both opened. It shall be apparent that recirculation may be effected with or without turning on the primary heating system 8. As temperature sensor 39 indicates a consistent and sufficiently high temperature, the primary heating system 8 may be turned off leaving the pump 28 on and valve 35 opened such that recirculation can continue via the recirculation line 140 and the input line 138 to the variable volume holding tank to remove residual heat from the primary heating system 8.

Thus, having broadly outlined the more important features of the present invention in order that the detailed description thereof may be better understood, and that the present contribution to the art may be better appreciated, there are, of course, additional features of the present invention that will be described herein and will form a part of the subject matter of this specification.

As such, those skilled in the art will appreciate that the conception, upon which this disclosure is based, may readily be utilized as a basis for the designing of other structures, methods and systems for carrying out the several purposes of the present invention. It is important, therefore, that the claims be regarded as including such equivalent construction insofar as they do not depart from the spirit and scope of the conception regarded as the present invention. 

We claim:
 1. A water heating control system for automatically reducing delay in delivering a volume of water at a flowrate, the volume of water is heated from a first temperature to a target temperature during a time interval of a day, said water heating control system comprising: (a) a device for aiding in heating the volume of water at said flowrate from said first temperature to said target temperature; (b) a historical flow demand corresponding to the time interval of a day; (c) a current flow demand corresponding to the time interval of a day; and (d) a controller configured for calculating a new flow demand based on said historical flow demand and said current flow demand, wherein if said new flow demand exceeds a threshold, said device is configured to be activated during the time interval of a day and said new flow demand is configured to be set as said historical flow demand for the time interval of a day.
 2. The water heating control system of claim 1, wherein said historical flow demand is selected from the group consisting of historical average flowrate, historical average flow volume, historical average frequency of flow request, historical frequency of user presence detection and any combinations thereof.
 3. The water heating system of claim 1, wherein said current flow demand is sustained water flowrate of at or above about 0.5 Gallons Per Minute (GPM) for at least about 5 minutes.
 4. The water heating control system of claim 1, wherein said current flow demand is current flowrate.
 5. The water heating control system of claim 1, wherein said device is selected from the group consisting of an internal recirculating flow circuit, an external recirculating flow circuit, a burner, a burner and blower combination, a valve, a pump and any combinations thereof.
 6. The water heating control system of claim 1, wherein said new flow demand is configured to be calculated by applying a first weighting factor to said historical flow demand to result in a first intermediate result and a second weighting factor to said current flow demand to result in a second intermediate result, wherein said second weighting factor is a complementary percentage of said first weighting factor.
 7. The water heating control system of claim 1, wherein the time interval of a day covers a span of about 15 minutes.
 8. The water heating control system of claim 1, wherein said device is an external recirculating flow circuit adapted to recirculate the volume of water in a variable volume holding tank.
 9. The water heating control system of claim 1, wherein said device comprises a burner and an external recirculating flow circuit adapted to recirculate the volume of water in a variable volume holding tank.
 10. A water heating control system for automatically reducing delay in delivering a volume of water at a flowrate, the volume of water is heated from a first temperature to a target temperature during a time interval of a day, said water heating control system comprising: (a) a device for aiding in heating the volume of water at said flowrate from said first temperature to said target temperature; (b) a historical flow demand corresponding to the time interval of a day; (c) a current flow demand corresponding to the time interval of a day; and (d) a controller configured for calculating a new flow demand based on said historical flow demand and said current flow demand, wherein said new flow demand is configured to be calculated by applying a first weighting factor to said historical flow demand to result in a first intermediate result and a second weighting factor to said current flow demand to result in a second intermediate result, wherein said second weighting factor is a complementary percentage of said first weighting factor, wherein if said new flow demand exceeds a threshold, said device is configured to be activated during the time interval of a day and said new flow demand is configured to be set as said historical flow demand for the time interval of a day.
 11. The water heating control system of claim 10, wherein said historical flow demand is selected from the group consisting of historical average flowrate, historical average flow volume, historical average frequency of flow request, historical frequency of user presence detection and any combinations thereof.
 12. The water heating control system of claim 10, wherein said current flow demand is sustained water flowrate of at or above about 0.5 Gallons Per Minute (GPM) for at least about 5 minutes.
 13. The water heating control system of claim 10, wherein said current flow demand is current flowrate.
 14. The water heating control system of claim 10, wherein said device is selected from the group consisting of an internal recirculating flow circuit, an external recirculating flow circuit, a burner, a burner and blower combination, a valve, a pump and any combinations thereof.
 15. The water heating control system of claim 10, wherein the time interval of a day covers a span of about 15 minutes.
 16. The water heating control system of claim 10, wherein said device is an external recirculating flow circuit adapted to recirculate the volume of water in a variable volume holding tank.
 17. The water heating control system of claim 10, wherein said device comprises a burner and an external recirculating flow circuit adapted to recirculate the volume of water in a variable volume holding tank. 